cisco data center guide
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Cisco Systems, Inc. All rights reserved.
Cisco Systems, Inc., 170 West Tasman Drive, San Jose, CA 95134-1706 USA
Data CenterSite Selection for BusinessContinuance
Preface 5
Intended Audience 6
Chapter 1Site Selection Overview 6
The Need for Site Selection 6
Business Goals and Requirements 7
The Problem 7
The Solution 7
Single Site Architecture 8
Multi-Site Architecture 8
Application Overview 8
Legacy Applications 8
Non-Legacy Applications 9
Application Requirements 9
Benefits of Distributed Data Centers 10
Site-to-Site Recovery 10
Multi-Site Load Distribution 10
Solution Topologies 11
Site-to-Site Recovery 11
User to Application Recovery 14
Database-to-Database Recovery 14
Storage-to-Storage Recovery 14
Multi-Site Topology 15
Conclusion 17
Chapter 2 Site Selection Technologies 17
Site Selection 17
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DNS-Based Site Selection 18
HTTP Redirection 19
Route Health Injection 20
Supporting Platforms 21
Global Site Selector 21WebNS and Global Server Load Balancing 22
Application Control Engine (ACE) for Catalyst 6500 23
Conclusion 24
Chapter 3Site-to-Site Recovery Using DNS 25
Overview 25
Benefits 25
Hardware and Software Requirements 25
Design Details 26
Design Goals 26
Redundancy 26
High Availability 26
Scalability 26
Security 27
Other Requirements 27
Design Topologies 27
Site-to-Site Recovery 27
Implementation Details 28
Primary Standby 29
Redundancy 29High Availability 31
Scalability 31
Basic Configuration 31
Site-to-Site Recovery 33
Site Selection Method 33
Configuration 33
Conclusion 35
Chapter 4Multi-Site Load Distribution Using DNS 35
Overview 35
Benefits 35
Hardware and Software Requirements 36
Design Details 36
Design Goals 36
Redundancy 36
High Availability 36
Scalability 37
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Security 37
Other Requirements 37
Design Topologies 37
Multi-Site Load Distribution 38
Site 1, Site 2, Site 3 38Implementation Details 39
Redundancy 40
High Availability 41
Scalability 42
Basic Configuration 42
Multi-Site Load Distribution 43
Site Selection Methods 44
Configuration 46
Least Loaded Configuration 46
Conclusion 48
Chapter 5Site-to-Site Recovery Using IGP and BGP 48
Overview 48
Site-to-Site Recovery Topology 49
Design Details 51
Design Goals 51
Redundancy 51
High Availability 52
Application Requirements 52
Additional Design Goals 52Design Recommendations 53
Advantages and Disadvantages of Using ACE 54
Site-to-Site Recovery using BGP 54
AS Prepending 55
BGP Conditional Advertisements 55
Design Limitations 56
Recovery Implementation Details Using RHI 56
High Availability 58
Configuration Examples 58
Configuring the VLAN Interface Connected to the Core Routers 58
Configuring the Server Farm 59
Configuring the Server-Side VLAN 59
Configuring the Virtual Server 59
Injecting the Route into the MSFC Routing Table 59
Redistributing Routes into OSPF 60
Changing Route Metrics 60
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Routing Advertisements in RHI 61
Restrictions and Limitations 62
Recovery Implementation Details using BGP 63
AS Prepending 63
Primary Site Configuration 64Standby Site Configuration 65
BGP Conditional Advertisement 66
Primary Site Configuration 67
Standby Site Configuration 68
Restrictions and Limitations 70
Conclusion 71
Chapter 6Site-to-Site Load Distribution Using IGP and BGP 71
Overview 72
Design Details 72
Active/Active Site-to-Site Load Distribution 72
Implementation Details for Active/Active Scenarios 73
OSPF Route Redistribution and Summarization 74
BGP Route Redistribution and Route Preference 75
BGP Configuration of Primary Site Edge Router 75
BGP Configuration of Secondary Site Edge Router 76
Load Balancing Without IGP Between Sites 77
Routes During Steady State 78
Routes After All Servers in Primary Site Are Down 78
Limitations and Restrictions 79Subnet-Based Load Balancing Using IGP Between Sites 79
Changing IGP Cost for Site Maintenance 80
Routes During Steady State 81
Test Cases 82
Test Case 1Primary Edge Link (f2/0) to ISP1 Goes Down 83
Test Case 2Primary Edge Link (f2/0) to ISP1 and Link (f3/0) to ISP2 Goes Down 83
Test Case 3Primary Data Center ACE Goes Down 85
Limitations and Restrictions 86
Application-Based Load Balancing Using IGP Between Sites 86
Configuration on Primary Site 87
Primary Data Center Catalyst 6500 87
Primary Data Center Edge Router 87
Configuration on Secondary Site 88
Secondary Data Center Catalyst 6500 88
Secondary Data Center Edge Router 88
Routes During Steady State 89
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Preface
Primary Edge Router 89
Secondary Edge Router 89
Test Case 1Servers Down at Primary Site 89
Primary Edge Router 89
Secondary Edge Router 89Limitations and Restrictions 90
Using NAT in Active/Active Load Balancing Solutions 90
Primary Site Edge Router Configuration 91
Secondary Site Edge Router Configuration 92
Steady State Routes 93
Routes When Servers in Primary Data Center Goes Down 95
Route Health Injection 96
Glossary 98
C 98
D 98
G 99
H 99
N 99
O 99
R 99
S 99
T 100
U 100
V 100W 100
PrefaceFor small, medium, and large businesses, it is critical to provide high availability of data for both
customers and employees. The objective behind disaster recovery and business continuance plans is
accessibility to data anywhere and at any time. Meeting these objectives is all but impossible with a
single data center. The single data center is a single point of failure if a catastrophic event occurs. The
business comes to a standstill until the data center is rebuilt and the applications and data are restored.
As mission-critical applications have been Web-enabled, the IT professional must understand how the
application will withstand an array of disruptions ranging from catastrophic natural disasters, to acts of
terrorism, to technical glitches. To effectively react to a business continuance situation, all business
organizations must have a comprehensive disaster recovery plan involving several elements, including:
Compliance with federal regulations
Human health and safety
Reoccupation of an effected site
Recovery of vital records
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Recovery information systems (including LAN/WAN recovery), electronics, and
telecommunications recovery
Enterprises can realize application scalability and high availability and increased redundancy by
deploying multiple data centers, also known as distributed data centers (DDC). This Solutions Reference
Network Design (SRND) guide discusses the benefits, technologies, and platforms related to designing
distributed data centers. More importantly, this SRND discusses disaster recovery and businesscontinuance, which are two key problems addressed by deploying a DDC.
Intended Audience
This document is for intended for network design architects and support engineers who are responsible
for planning, designing, implementing, and operating networks.
Chapter 1Site Selection Overview
This chapter describes how application recovery, disaster recovery, and business continuance areachieved through site selection, site-to-site recovery, and load balancing. It includes the following
sections:
The Need for Site Selection, page 6
Application Overview, page 8
Benefits of Distributed Data Centers, page 10
Solution Topologies, page 11
Conclusion, page 17
The Need for Site SelectionCentralized data centers have helped many Enterprises achieve substantial productivity gains and cost
savings. These data centers house mission-critical applications, which must be highly available. The
demand on data centers is therefore higher than ever before. Data center design must focus on scaling
methodology and achieving high availability. A disaster in a single data center that houses Enterprise
applications and data has a crippling affect on the ability of an Enterprise to conduct business.
Enterprises must be able to survive any natural or man-made disaster that may affect the data center.
Enterprises can achieve application scalability, high availability, and redundancy by deploying
distributed data centers. This document discusses the benefits, technologies, and platforms related to
designing distributed data centers, disaster recovery, and business continuance.
For small, medium and large businesses, it is critical to provide high availability of data for both
customers and employees. The goal of disaster recovery and business continuance plans is guaranteedaccessibility to data anywhere and at any time. Meeting this objective is all but impossible with a single
data center, which is a single point of failure if a catastrophic event occurs. In a disaster scenario, the
business comes to a standstill until the single data center is rebuilt and the applications and data are
restored.
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Business Goals and Requirements
Before going into the details, it is important to keep in mind why organizations use data centers and
require business continuance strategies. Technology allows businesses to be productive and to quickly
react to business environment changes. Data centers are one of the most important business assets and
data is the key element. Data must be protected, preserved, and highly available.For a business to access data from anywhere and at any time, the data center must be operational around
the clock, under any circumstances. In addition to high availability, as the business grows, businesses
should be able to scale the data center, while protecting existing capital investments. In summary, data
is an important aspect of business and from this perspective; the business goal is to achieve redundancy,
high availability, and scalability. Securing the data must be the highest priority.
The Problem
In todays electronic economy, any application downtime quickly threatens a businesss livelihood.
Enterprises lose thousands of dollars in productivity and revenue for every minute of IT downtime. A
recent study by Price Waterhouse Coopers revealed that globally network downtime costs business $1.6Trillion in the last year. This equated to 4.4 Billion per day, $182 million per hour, or $51,000 per second.
In the U.S. with companies with more than 1000 employees, it is a loss of $266 Billion in the last year.
A similar Forrester Research survey of 250 Fortune 1000 companies revealed that these businesses lose
a staggering US$13,000 for each minute that an Enterprise resource planning (ERP) application is
inaccessible. The cost of supply-chain management application downtime runs a close second at
US$11,000 per minute, followed by e-commerce (US$10,000).
To avoid costly disruptions, Enterprises are turning to intelligent networking capabilities to distribute
and load balance their corporate data centerswhere many of their core business applications reside.
The intelligence now available in IP networking devices can determine many variables about the content
of an IP packet. Based on this information, the network can direct traffic to the best available and least
loaded sites and servers that will provide the fastest-and best-response.
Business continuance and disaster recovery are important goals for businesses. According to the YankeeGroup, business continuity is a strategy that outlines plans and procedures to keep business operations,
such as sales, manufacturing and inventory applications, 100% available.
Companies embracing e-business applications must adopt strategies that keep application services up
and running 24 x 7 and ensure that business critical information is secure and protected from corruption
or loss. In addition to high availability, the ability to scale as the business grows is also important.
The Solution
Resilient networks provide business resilience. A business continuance strategy for application data that
provides this resilience involves two steps.
Replicating data, either synchronously or asynchronously
Directing users to the recovered data
Data needs to be replicated synchronously or at regular intervals (asynchronously). It must then be
retrieved and restored when needed. The intervals at which data is backed up is the critical component
of a business continuance strategy. The requirements of the business and its applications dictate the
interval at which the data is replicated. In the event of a failure, the backed up data must be restored, and
applications must be enabled with the restored data.
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The second part of the solution is to provide access and direct users to the recovered data. The main goal
of business continuance is to minimize business losses by reducing the time between the loss of data and
its full recovery and availability for use. For example, if data from a sales order is lost, it represents a
loss for the business unless the information is recovered and processed in time to satisfy the customer.
Single Site Architecture
When you consider business continuance requirements, it is clear that building a single data center can
be very risky. Although good design protects access to critical information if hardware or software
breaks down at the data center, that doesn't help if the entire data center becomes inaccessible. To deal
with the catastrophic failure of an entire site, applications and information must be replicated at a
different location, which requires building more than one data center.
Multi-Site Architecture
When application data is dupl icated at multiple data centers, clients go to the available data center in the
event of catastrophic failure at one site. Data centers can also be used concurrently to improveperformance and scalability. Building multiple data centers is analogous to building a global server farm,
which increases the number of requests and number of clients that can be handled.
Application information, often referred to as content, includes critical application information, static
data (such as web pages), and dynamically generated data.
After content is distributed to multiple data centers, you need to manage the requests for the distributed
content. You need to manage the load by routing user requests for content to the appropriate data center.
The selection of the appropriate data center can be based on server availability, content availability,
network distance from the client to the data center, and other parameters.
Application Overview
The following sections provide an overview of the applications at the heart of the data center, which can
be broadly classified into two categories:
Legacy Applications
Non-Legacy Applications
Legacy Applications
Legacy applications are based on programming languages, hardware platforms, operating systems, and
other technology that were once state-of-the art, but are now outmoded. Many large Enterprises have
legacy applications and databases that serve critical business needs. Organizations are often challengedto keep legacy application running during the conversion to more efficient code that makes use of newer
technology and software programming techniques. Integrating legacy applications with more modern
applications and subsystems is also a common challenge.
In the past, applications were tailored for a specific operating system or hardware platform. It is common
today for organizations to migrate legacy applications to newer platforms and systems that follow open,
standard programming interfaces. This makes it easier to upgrade software applications in the future
without having to completely rewrite them. During this process of migration, organizations also have a
good opportunity to consolidate and redesign their server infrastructure.
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In addition to moving to newer applications, operating systems, platforms, and languages, Enterprises
are redistributing their applications and data to different locations. In general, legacy applications must
continue to run on the platforms for which they were developed. Typically, new development
environments provide ways to support legacy applications and data. With many tools, newer programs
can continue to access legacy databases.
In an IP environment, the legacy applications typically have hard-coded IP addresses for communicatingwith servers without relying on DNS.
Non-Legacy Applications
The current trend is to provide user-friendly front-ends to applications, especially through the
proliferation of HTTP clients running web-based applications. Newer applications tend to follow open
standards so that it becomes possible to interoperate with other applications and data from other vendors.
Migrating or upgrading applications becomes easier due to the deployment of standards-based
applications. It is also common for Enterprises to build three-tier server farm architectures that support
these modern applications. In addition to using DNS for domain name resolution, newer applications
often use HTTP and other Internet protocols and depend on various methods of distribution and
redirection.
Application Requirements
Applications store, retrieve and modify data based on client input. Typically, application requirements
mirror business requirements for high availability, security, and scalability. Applications must be capable
of supporting a large number of users and be able to provide redundancy within the data center to protect
against hardware and software failures. Deploying applications at multiple data centers can help scale
the number of users. As mentioned earlier, distributed data centers also eliminate a single point of failure
and allow applications to provide high availability. Figure 1 provides an idea of application
requirements.
Figure 1 Application Requirements
Most modern applications have high requirements for availability, security, and scalability.
ScalabilityApplication
87016
HA Security
ERP/Mfg High HighHigh
E-Commerce High HighHigh
High High
CRM High HighHigh
Hospital Apps High High
E-mail Medium MediumHigh
Financial
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Benefits of Distributed Data Centers
The goal of deploying multiple data centers is to provide redundancy, scalability and high availability.
Redundancy is the first line of defense against any failure. Redundancy within a data center protects
against link failure, equipment failure and application failure and protects businesses from both direct
and indirect losses. A business continuance strategy for application data backup that addresses theseissues includes data backup, restoration, and disaster recovery. Data backup and restoration are critical
components of a business continuance strategy, which include the following:
Archiving data for protection against data loss and corruption, or to meet regulatory requirements
Performing remote replication of data for distribution of content, application testing, disaster
protection, and data center migration
Providing non-intrusive replication technologies that do not impact production systems and still
meet shrinking backup window requirements
Protecting critical e-business applications that require a robust disaster recovery infrastructure.
Providing real-time disaster recovery solutions, such as synchronous mirroring, allow companies to
safeguard their data operations by:
Ensuring uninterrupted mission-critical services to employees, customers, and partners
Guaranteeing that mission-critical data is securely and remotely mirrored to avoid any data loss
in the event of a disaster
Another benefit of deploying distributed data centers is in the Wide-Area Bandwidth savings. As
companies extend applications throughout their global or dispersed organization, they can be hindered
by limited Wide Area Network (WAN) bandwidth. For instance, an international bank has 500 remote
offices world-wide that are supported by six distributed data centers. This bank wants to roll-out
sophisticated, content-rich applications to all their offices without upgrading the entire WAN
infrastructure. An intelligent site selection solution that can point the client to a local data center for
content requests instead of one located remotely will save costly bandwidth and upgrade expenses.
The following sections describe how these aspects of a business continuance strategy are supported
through deploying distributed data centers.
Site-to-Site Recovery
Deploying more than one data center provides redundancy through site-to-site recovery mechanisms.
Site-to-site recovery is the ability to recover from a site failure by ensuring failover to a secondary or
backup site. As companies realize the productivity gains the network brings to their businesses, more
and more companies are moving towards a distributed data center infrastructure, which achieves
application redundancy and the other goals of a business continuance strategy.
Multi-Site Load Distribution
Distributing applications among multiple sites provides a more efficient, cost-effective use of global
resources, ensures scalable content, and gives end users better response time. Routing clients to a site
based on load conditions and the health of the site results in scalability for high demand and ensures high
availability.
You can load balance many of the applications that use standard HTTP, TCP or UDP, including mail,
news, chat, and lightweight directory access protocol (LDAP). Multi-site load distribution provides
enhanced scalability for a variety of mission-critical e-Business applications. However, these benefits
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come with some hurdles. Some of the challenges include mirroring database state information and
mirroring data and session information across multiple data centers. Many application vendors are
wrestling with these issues. Providing the underlying infrastructure required to facilitate mirroring helps
simplify the problem by providing high bandwidth and a high-speed connection between the data
centers.
As mentioned earlier, you can improve data center availability and balance the load between sites byrouting end users to the appropriate data centers. You can use different criteria to route end users to
different data centers. In most cases, routing users to a data center that is geographically closer improves
the response time. This is referred to as proximity-based site selection. In addition to this, you can route
users to different data centers based on the load at the data center and on the availability of a specific
application.
You can distribute applications like video on demand (VoD) or media on demand (MoD) across different
data centers. Load distribution based on proximity plays an important role when delivering multimedia
to end-users. In this instance, clients are redirected to the closest data center. This improves the end users
experience and helps reduce congestion on the network.
Access to applications is limited by a number of factors related to hardware, software, and the network
architecture. To accommodate anticipated demand, you should estimate peak traffic loads on the system
to determine the number of nodes required.Distributed data centers let you deploy the same application across multiple sites, increasing scalability
and providing redundancyboth of which are key goals when supporting mission-critical applications
Solution Topologies
This section describes some general topologies for using distributed data centers to implement a business
continuance strategy. It includes the following topics:
Site-to-site recovery
User-to-application recovery
Database-to-database recovery
Storage-to-storage recovery
Site-to-Site Recovery
Typically, in a data center, the web servers, application servers, databases, and storage devices are
organized in a multi-tier architecture, referred to as an instance of the multi-tier architecture or N-Tier
architecture. This document describes the most common N-Tier model, which is the three-tier model. A
three-tier architecture has the following components:
Front-end layer
Application layer Back-end layer
The front-end layer or presentation tier provides the client interface and serves information in response
to client requests. The servers in this tier assemble the information and present it to the client. This layer
includes DNS, FTP, SMTP and other servers with a generic purpose. The application tier, also known as
middleware or business logic, contains the applications that process the requests for information and
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provide the logic that generates or fulfills dynamic content. This tier runs the processes needed to
assemble the dynamic content and plays the key role of interconnecting the front-end and back-end tiers.
Various types of databases form the back end tier.
Typically, a disaster recovery or a business continuance solution involves two data centers, as depicted
in Figure 2.
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Figure 2 Distributed Data Center Model
There are two main topologies from a solutions perspective:
Hot standby
Warm standby
Front-end Layer
Application Layer
Back-end Layer
Serviceprovider
A
Serviceprovider
B
Internet
Internetedge
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ESCON
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Primary Data Center Secondary Data Center
DWDMRing
ONS 15xxxDWDM
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Internalnetwork
InternetedgeInternal
network
Storage
Metro Optical
Server
Farms
Core switches
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In a hot standby solution, the secondary data center has some applications running actively and has some
traffic processing responsibilities. Resources are not kept idle in the secondary data center, and this
improves overall application scalability and equipment utilization.
In a warm standby solution, the applications at the secondary data center are active at all times but the
traffic is only processed by the secondary data center when the primary data center goes out of service.
Note that in Figure 2, the multi-tier architecture is replicated at both the primary and secondary datacenters.
User to Application Recovery
When a catastrophic failure occurs at a data center and connectivity with the application is lost, the client
application might try to reconnect to the cached IP address of the server. Ultimately, you have to restart
the application on the desktop because the primary data center is not available. When the client
application connects to the remote server, it resolves the domain to an IP address. In a recovery scenario,
the new IP address belongs to the secondary data center. The application is unaware that the secondary
data center is active and that the request has been rerouted. The site selection devices monitor the
applications at both data centers and route requests to the appropriate IP address based on application
availability.
The alternative is to use the same IP address in both data centers and if the application in one data center
becomes available the user is routed to the application in the standby data center. If the applications are
stateful, the user can still connect to the application in the standby data center. However, a new
connection to the standby data center is used because application state information is not exchanged
between the data centers.
Database-to-Database Recovery
Databases maintain keep-alive traffic and session state information between the primary and secondary
data centers. Like the application tier, the database tier has to update the state information to the
secondary data center. Database state information updates tend to be chattier than application stateinformation updates. Database updates consume more bandwidth and have a drastic impact on the
corporate network if they happen frequently during regular business hours. Database synchronization
benefits from the backend network infrastructure introduced to support the application tier. During a
catastrophic failure at the primary data center, the secondary data center becomes active and the database
rolls back to the previous update.
Storage-to-Storage Recovery
The destination for all application transactions is the storage media, like disk arrays, which are part of
the data center. These disks are backed up locally using tapes and can be backed up either synchronously
or asynchronously to the remote data center. If the data is backed up using disk arrays, after acatastrophic failure, the data is recovered from the tapes at an alternate data center, which requires a great
deal of time and effort.
In asynchronous backup, data is written to the secondary data center at regular intervals. All the data
saved on the local disk arrays for a specific window of operation is transferred to the secondary data
center. When a disaster occurs, the data is retrieved from the previous update and operation resumes,
starting at the last update. With this mechanism, data is rolled back to the previous update. This method
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has less recovery overhead when compared to tape backup mechanism and recovery is quick. Although
some data loss is still likely, nearly all of the essential data is recovered immediately after a catastrophic
failure.
Organizations with a low tolerance for downtime and lost data use synchronous data backup. With
synchronous backup, data is written to the remote or secondary data center every time the data is written
at the primary data center. If there is a catastrophic failure, the secondary data center takes over withalmost no loss of data. The end user, after completing the user to application recovery process can access
the secondary data center with almost no loss of data. Close to 100% of all data is recovered and there
is virtually no business impact.
Multi-Site Topology
It is difficult to provide a specific multi-site topology. Multi-site topology might mean multiple sites
connected together using different network technologies. The number of sites and the location of these
sites depends on the business. Various factors like the number of users, the user location, and business
continuance plans, dictate where the sites are located and how they are interconnected. Figure 3provides
one example of a multi-site topology.
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Figure 3 Multi-Site Architecture
In a local server load-balancing environment, scalability is achieved by deploying a server farm and
front-ending that server farm with a content switch. Multiple data centers can be thought of as islands
of server farms with site selection technology front-ending these servers and directing end users to
different data centers. The applications are distributed across different data centers. The clients
DWDM Ring
Serviceprovider
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Serviceprovider
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Internet
Internetedge
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ESCON
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Data center 1
ONS 15xxxDWDM
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Data center 3
Data center 2
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requesting connection to these applications get directed to different data centers based on various
criteria. This is referred to as a site selection method. Different site selection methods include least
loaded, round robin, preferred sites and source IP hash.
ConclusionData is such a valuable corporate asset in the information age that accessibility to this data around the
clock is essential to allow organizations to compete effectively. Building redundancy into the application
environment helps keep information available around the clock. Because the time spent recovering from
disaster has a significant impact on operations; business continuance has become an extremely critical
network design goal. Statistical evidence shows a direct relationship between a successful business
continuance plan and the general health of a business in the face of disaster. The Return on Investment
(ROI) is justified by the costs of the direct and indirect losses incurred by a critical application outage.
For these and the other compelling reasons described in this paper, all large Enterprises must seriously
consider implementing business continuance strategies that include distributed data centers.
Chapter 2 Site Selection TechnologiesSeveral technologies make up a complete site-to-site recovery and multi-site load distribution solution.
In a client to server communication, the client looks for the IP address of the server before
communicating with the server. When the server is found, the client communicates with the server and
completes a transaction. This transaction data is stored in the data center. The technology that deals with
routing the client to the appropriate server is at the front end of data centers. In a distributed data center
environment, the end users have to be routed to the data center where the applications are active. The
technology that is at the front end of distributed data centers is called Request Routing.
Site Selection
Most applications use some form of address resolution to get the IP address of the servers with which
they communicate. Some examples of the applications that use address resolution mechanisms to
communicate with the servers or hosts are Web browsers, telnet, and thin clients on users desktop. Once
an IP address is obtained, these applications connect to the servers in a secure or non-secure way, based
on the application requirements, to carry out the transaction.
Address resolution can be further extended to include server health tracking. Tracking sever health
allows the address resolution mechanism to select the best server to handle client requests and adds high
availability to the solution. In a distributed data center environment, where redundant servers which
serve the same purpose at geographically distant data centers are deployed, the clients can be directed
to the appropriate data center during the address resolution process. This method of directing the clients
to the appropriate server by keeping track of server health is called Request Routing.
There are three methods of site selection mechanisms to connect clients to the appropriate data center:
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DNS-based request routing
HTTP redirection
Route Health Injection (RHI) with BGP/IGP
DNS-Based Site SelectionThe first solution, depicted in Figure 4, is based on DNS. Normally, the first step when connecting to a
server is resolving the domain name to an IP address. The clients resolution process becomes a DNS
query to the local DNS server, which then actively iterates over the DNS server hierarchy on the
Internet/Intranet until it reaches the target DNS server. The target DNS server finally issues the IP
address.
Figure 4 Basic DNS Operation
1. The client requests to resolve www.foo.com.
2. The DNS proxy sends a request to the root DNS. The root DNS responds with an address of the root
DNS for foo.com.
3. The DNS proxy requests the root DNS for foo.com. The response comes back with the IP address
of the authoritative DNS server for foo.com.
4. The DNS proxy requests the authoritative DNS server for foo.com. The response comes back with
an IP address for www.foo.com.
5. The DNS proxy requests the authoritative DNS server for www.foo.com. The response comes back
with an IP address of the web server.
6. The DNS proxy responds to the client with the IP address of the web server.
7. The client establishes a connection with the web server.
At its most basic level, the DNS provides a distributed database of name-to-address mappings spread
across a hierarchy of domains and sub domains with each domain administered independently by an
authoritative name server. Name servers store the mapping of names to addresses in resource records.
Each record keeps an associated time to live (TTL) field that determines how long the entry is cached by
other name servers.
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Authoritative DNS forwww.foo.com,"www.foo.com = 208.10.4.17"
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Name servers implement iterative or recursive queries:
Iterative queries return either an answer to the query from its local database (A-record), or a referral
to another name server that is able to answer the query (NS-record).
Recursive queries return a final answer (A-record), querying all other name servers necessary to
resolve the name.
Most name servers within the hierarchy send and accept only iterative queries. Local name servers,
however, typically accept recursive queries from clients. Recursive queries place most of the burden of
resolution on a single name server.
In recursion, a client resolver sends a recursive query to a name server for information about a particular
domain name. The queried name server is then obliged to respond with the requested data, or with an
error indicating that the data of the requested type or the domain name does not exist. Because the query
was recursive, the name server cannot refer the querier to a different name server. If the queried name
server is not authoritative for the data requested, it must query other name servers for the answer. It could
send recursive queries to those name servers, thereby obliging them to find the answer and return it (and
passing the buck). Alternately, the DNS proxy could send iterative queries and be referred to other name
servers for the name it is trying to locate. Current implementations tend to be polite and do the latter,
following the referrals until an answer is found.
Iterative resolution, on the other hand, does not require nearly as much on the part of the queried name
server. In iterative resolution, a name server simply gives the best answer it already knows back to the
querier. There is no additional querying required.
The queried name server consults its local data, including its cache, looking for the requested data. If it
does not find the data, it makes the best attempt to give the querier data that helps it continue the
resolution process. Usually these are names and addresses of other name servers.
In iterative resolution, a clients resolver queries a local name server, which then queries a number of
other name servers in pursuit of an answer for the resolver. Each name server it queries refers it to
another name server further down the DNS name space and closer to the data sought. Finally, the local
name server queries the name server authoritative for the data requested, which returns an answer.
HTTP Redirection
Many applications currently available today have a browser front end. The browsers have built in http
redirection built so that they can communicate with the secondary server if the primary servers are out
of service. In HTTP redirection, the client goes through the address resolution process once. In the event
that the primary server is not accessible, the client gets redirected to a secondary server with out having
to repeat the address resolution process.
Typically, HTTP redirection works like this. HTTP has a mechanism for redirecting a user to a new
location. This is referred to as HTTP-Redirection or HTTP-307 (the HTTP return code for redirection).
The client, after resolving the IP address of the server, establishes a TCP session with the server. The
server parses the first HTTP get request. The server now has visibility of the actual content being
requested and the clients IP address. If redirection is required, the server issues an HTTP Redirect (307)to the client and sends the client to the site that has the exact content requested. The client then
establishes a TCP session with the new host and requests the actual content.
The HTTP redirection mechanism is depicted in Figure 5.
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Figure 5 Basic Operation of HTTP Redirect
The advantages of HTTP redirection are: Visibility into the content being requested.
Visibility of the clients IP address helps in choosing the best site for the client in multi-site load
distribution.
The disadvantages of HTTP redirection are:
In order for redirection to work, the client has to always go to the main site first and then get
redirected to an alternate site.
Book marking issues arise because you can bookmark your browser to a particular site and not the
global http://www.foo.com site, thus bypassing the request routing system.
HTTP redirects only work for HTTP traffic. Some applications, which do not have browser front
ends, do not support HTTP redirection.
Route Health Injection
Route Health Injection (RHI) is a mechanism that allows the same IP address to be used at two different
data centers. This means that the same IP address (host route) can be advertised with different metrics.
The upstream routers see both routes and insert the route with the better metric into its routing table.
When RHI is enabled on the device, it injects a static route in the devices routing table when VIPs
become available. This static route is withdrawn when the VIP is no longer active. In case of a failure of
the device, the alternate route is used by the upstream routers to reach the servers thereby providing high
availability. It is important to note that the host routes are advertised by the device only if the server is
healthy.
Note Most routers do not propagate host-route information to the Internet. Therefore, RHI, since it advertises
host routes, is normally restricted to intranets.
The same IP address can also be advertised from a different location, calling it the secondary location,
but with a different metric. The mechanism is exactly the same as in the previous case, with the only
difference being the route is advertised with a different metric.
HTTP/1.1 200 OKHost:www1.cisco.com
GET/HTTP/1.1Host:www1.cisco.com
Client talks to www1.cisco.com
for the remainder of the session87020
www1.cisco.com
3
Client's request to DNS resolves www.cisco.comto the IP address of the server
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For applications that serve Internet users, you can summarize the host routes at the Internet edge and
redistribute them into BGP. You can advertise these routes from the secondary site by using the
conditional advertisement feature of Cisco BGP,. This works as long as the IP address is active at the
primary site or as long as the links to the multiple service providers are active and do not advertise the
IP address from the secondary site.
The advantages of RHI are: Quick convergence (IGP convergence)
Self regulated, no dependency on external content routing devices
Ideal for business continuance and disaster recovery solutions
Single IP address
The disadvantages of RHI are:
Cannot be used for site-to-site load balancing because the routing table has only one entry. Typically
it is used only for active/standby configurations.
Supporting PlatformsCisco has various products that support request routing for distributed data centers. Each product has
different capabilities. All the supporting products are described below.
ACE Global Site Selector (GSS 4492R)
Application Control Engine (ACE) Module for Cat6K platforms
Global Site Selector
The Cisco GSS 4492R load balances distributed data centers. GSS interoperates with server load
balancing products like the Cisco CSS 11000 and CSS 11500 Content Services Switch and the
Application Control Engine (ACE) for the Cisco Catalyst 6500 Series switches.
The Cisco GSS 4492R product delivers the following key capabilities:
Provides a scalable, dedicated hardware platform for Ciscos content switches to ensure applications
are always available, by detecting site outages or site congestion
Improves global data center or site selection process by using different site selection algorithms
Complements existing DNS infrastructure by providing centralized sub-domain management
The Cisco GSS 4492R allows businesses to deploy internet and intranet applications by directing clients
to a standby data center if a primary data-center outage occurs. The Cisco GSS 4492R continuously
monitors the load and health of the server load balancing devices at multiple data centers and can redirect
clients to a data center with least load. The load conditions are user defined at each data center.
The following are key features and benefits of GSS: Offers site persistence for e-commerce applications
Provides architecture critical for disaster recovery and multi-site deployments
Provides centralized command and control of DNS resolution process
Provides dedicated processing of DNS requests for greater performance and scalability
Offers DNS race feature. The Cisco GSS 4492R can direct clients in real time to the closest data
center based on round trip time (RTT) between the local DNS and the multiple sites.
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Supports a web-based graphical user interface (GUI) and wizard to simplify the configuration
Figure 6 Basic Operation of GSS
Figure 6 illustrates the basic operation of GSS, as summarized below:
1. The GSS probes for the server health and is aware of the server health and load.
2. The client requests to resolve the URL in the HTTP request.
3. The local DNS server performs the DNS query. The GSS responds with the IP address based on the
configured algorithm.
4. The client connects to the server.
WebNS and Global Server Load Balancing
The Cisco 11000 series Content Services Switch (CSS) provide both global server load balancing
(GSLB) and network proximity methods for content request distribution across multiple sites.
The Cisco 11000 series CSS is capable of GSLB of content requests across multiple sites, using content
intelligence to distribute the requests according to what is being requested, and where the content is
available. Network proximity is an enhanced version of GSLB that selects the closest or most proximate
web site based on measurements of round-trip time to the content consumers location. Network
proximity naturally provides a high degree of global persistence, because the proximity calculation is
typically identical for all requests from a given location (Local DNS) as long as the network topology
remains constant.
WebNS also provides a scalable solution that provides sticky site selection without sacrificing proximityor GSLB. In this enhanced version, the sticky database allows the network administrator to configure
how long a D-proxy remains sticky. The TTL value ranges from minutes to days.
Figure 7 explains the basic operation of GSLB using content services switch.
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Figure 7 Basic Operation of GSLB Using Content Services Switch
1. Each CSS probes for the server health and is aware of state of the servers and exchange the server
availability information using the TCP session.
2. The client requests to resolve www.foo.com.
3. The local DNS server performs the iterative DNS query and the CSS responds with the IP address
based on configuration.
4. The client connects to the server to complete the transaction.
Application Control Engine (ACE) for Catalyst 6500
The Cisco Application Control Engine (ACE) integrates advanced Layer 4-7 content switching into the
Cisco Catalyst 6500 Series or Cisco 7600 Series Internet Router. The ACE provides high-performance,
high-availability load balancing, while taking advantage of the complete set of Layer 2, Layer 3, and
QoS features inherent to the platform. The ACE can communicate directly with the Global Site Selctor
(GSS), for use in GSLB, and also supports the RHI feature.
Figure 8 provides an overview of how the route health injection works using ACE. When RHI is enabled
on ACE, the ACE injects a static route into the MSFCs routing table. This, in turn, is redistributed by
the MSFC.
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Figure 8 RHI with the ACE
1. Each ACE probes for the server health and if servers are available, puts in a static route into the
MSFC routing table which gets advertised with different metrics from the two Catalyst 6500s (the
same IP address gets advertised with different metrics from two locations).
2. The host routes are propagated to the upstream routers and the route with the best metric is used by
the upstream routers.
3. The client requests to resolve www.foo.com.
4. The local DNS server performs the iterative DNS query and responds with an IP address.
5. The client connects to the web server on the right because the route is advertised with a better metric.
Conclusion
Site selection ensures that the best data center handles client requests. Each mechanism comes with
advantages and disadvantages. There is no generic solution for all site-to-site recovery deployments.
Regardless of the site selection mechanism you choose, the Cisco product portfolio supports all three
site selection mechanisms.
When deploying the solution, you should consider the following:
Is it Web based application?
Is DNS caching an issue?
Is it an Active-Active site or Active-Standby site?
All the solutions except for HTTP Redirection redirect traffic to an alternate site based on the
reachability/availability of the applications.
HTTP redirection relies on the HTTP Redirection error code to be received before the client is
redirected to an alternate site. In disaster situations this might not be an appropriate solution.
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Chapter 3Site-to-Site Recovery Using DNSThis chapter focuses on the design and deployment of distributed data centers for disaster recovery and
business continuance. It explores interoperability between the GSS and the ACE and also provides
details of relevant algorithms used in multi-site load distribution. These designs are based on request
routing (formerly content routing) products and the ACE server load balancing product.You can achieve redundancy and high availability by deploying multiple data centers and distributing
applications across those data centers. This chapter focuses on the design and deployment of distributed
data centers using the Global Site Selector (GSS) and the Application Control Engine (ACE).
Overview
The challenge of site selection to recover from site failures is to ensure that transaction requests from
clients are directed to the most appropriate server load balancing device at the geographically distant
data center. Geographic Site Selection requires control points for all transaction requests destined to any
data center. The point of control for a geographic load-distribution function resides within DNS. Most
clients must contact a DNS server to get an IP address to request service from a server. Because,geographically replicated content and applications reside on servers with unique IP addresses, unique
DNS responses can be provided to queries for the same URLs or applications based on site or application
availability.
Benefits
Site-to-site recovery enables businesses to provide redundancy in case of disasters at the primary data
centers. Redundancy and high availability of business critical applications are the key benefits of
site-to-site recovery.
Hardware and Software Requirements
The table below lists different hardware and software required to support site-to-site recovery and
multi-site load distribution. The GSS interoperates with the ACE and CSS. It also works with other
server load balancing products, but some of the features, like the least loaded connections and shared
keepalive features, cannot be used with other server load balancers. In subsequent sections of this
document, interoperability of the GSS and the ACE is described.
Product Release Platforms
Global Site Selector (GSS) 2.0.2.0.0 GSS-4492
Application Control Engine(ACE)
1.6.1 SLB complex for Catalyst 6Kplatforms
Cisco Network Registrar (CNR) 6.2.3.2 (this software version
was used for testing)
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Design Details
Design Goals
The basic design goal is to be able to direct clients to appropriate data center based on the configured
rules and the availability of the servers or services at the data center. The major design issues are:
Redundancy
High availability
Scalability
Security
Other requirements as necessary
Redundancy
Within a data center, redundancy is achieved at different layers. It could be link redundancy or device
redundancy. Redundancy provides a way of maintaining connectivity if there is a failure in the primarypath. This is achieved by deploying devices that support stateful failover.
There are times when the entire data center might go out of service due to an unforeseen reason. In such
cases, clients can be directed to a redundant data center. In the event of a data center fail over, it is
difficult to provide stateful failover. Although, there is some impact due to the failure of primary data
center, the impact is very small compared to not having a redundant design.
High Availability
High availability, from a global server load balancing point of view, is the ability to distribute the load
among available data centers. If, for any reason such as a hardware or software failure, over loaded data
center etc., it is determined that the new service requests cannot be handled by the data center, the request
is directed to a data center that can really handle the service request. It is the constant monitoring of
application availability and the load at a data center that helps in achieving high availability.
High availability is also prevalent at each layer of the network including Layer 2 and Layer 3. For a more
detailed description of how high availability is achieved within a data center, refer to the Data Center
Networking: Infrastructure SRND:
http://www.cisco.com/en/US/docs/solutions/Enterprise/Data_Center/DC_Infra2_5/DCI_SRND_2_5_b
ook.html.
Scalability
Scalability is an inherent element of distributed data center environment. Applications can be hosted at
multiple data centers to distribute the load across multiple data centers and make the applicationsscalable and highly available. The design should be able to support the growth both in number of sites
and the number of DNS records without performance degradation and without over-hauling the design.
There are scaling limitations. The details are covered in Implementation Details, page 28.
http://www.cisco.com/en/US/docs/solutions/Enterprise/Data_Center/DC_Infra2_5/DCI_SRND_2_5_book.htmlhttp://www.cisco.com/en/US/docs/solutions/Enterprise/Data_Center/DC_Infra2_5/DCI_SRND_2_5_book.htmlhttp://www.cisco.com/en/US/docs/solutions/Enterprise/Data_Center/DC_Infra2_5/DCI_SRND_2_5_book.htmlhttp://www.cisco.com/en/US/docs/solutions/Enterprise/Data_Center/DC_Infra2_5/DCI_SRND_2_5_book.html -
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Security
Security is deployed as an end to end service in the data center. Deploying request routing devices should
not compromise security in the data center. For instance, the placement of authoritative DNS should
ensure that security requirements are met because of the amount and type of overhead traffic needed to
ensure application availability at each data center. Monitoring application availability might include
determining both the health and load on the applications.
Other Requirements
Other design requirements include meeting client and application requirements. For a business to
business client, the client has to stay with the same site as long as it is available for the length of the
transaction period (site persistence). In the case of a client accessing a streaming application, the client
should be directed to a topologically closest data center (proximity). Some other client and application
requirements include directing clients to the data center based on round trip time, IGP, and BGP metrics.
Ideally the design should be able to meet all these requirements.
Design TopologiesCisco offers several products that are available for multi-site load distribution solutions. There are
different topologies based on the products. All the topologies adhere to Ciscos design recommendations
and contain a layered approach. The layer which connects to dual service providers is known as the
Internet edge1.. At each layer, redundant devices are deployed for high availability. The core layer
provides connectivity to branch offices, remote users and campus users. This document is focused on the
GSS interoperating with the ACE.
Specific topologies covered are site-to-site recovery and multi-site load distribution topologies. Both the
topologies look similar except for some minor differences. Cisco recommends the GSS for both
site-to-site load distribution and multi-site load distribution. Although the GSS has its limitations, it
provides most required features in a single product.
Note The GSS does not support MX records, IGP and BGP metrics. MX records can be supported by
forwarding requests to devices that handle MX records such as Cisco Network Registrar (CNR).
Site-to-Site Recovery
Site-to-site recovery provides a way of recovering data center applications and data in case of an
unexpected outage. Sometimes, building redundancy into each layer of networking is not enough. This
leads to building standby data centers. Standby data centers host similar applications and databases. You
can replicate your data to the standby data center to minimize downtime in the event of an unexpected
failure at the primary data center.
Figure 9depicts the site-to-site recovery topology using the GSS as the request routing device. Typically,the request router is connected to the aggregate switch and the GSS is the authoritative DNS for the
domains in the data center. In this example, the GSS is connected to the access switch instead. This is
due to the link redundancy limitation. Connecting the request router to the access switch provides some
level of redundancy. If the aggregate switch fails, the request router is still reachable. More details are
provided in Implementation Details, page 28. Two other common places to deploy the GSS devices are
either in the Data Center Security Internet DMZ or an ISP collocation facility. This places the DNS
1. Multi-homing to dual ISPs is covered in more detail in the Data Center Networking: Internet Edge Design
SRND.
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resolution at the closest edge point so that traffic is not carried all the way to the aggregation or access
layers of the data center before being redirected to a secondary site. Typically the primary data center
connects to two ISPs through the Internet edge to achieve redundancy and the primary and secondary
data center are connected either by WAN or metro optical links to replicate data for recovery in case of
disasters at the primary data center. If disaster hits the primary data center, the end users or clients are
directed to the secondary data center where the same applications and data is available.
Figure 9 Site-to-Site Recovery
Implementation Details
Before getting into the details, this is an appropriate point to discuss the features common to both
site-to-site recovery and multi-site load distribution. The first one to consider are the GSS health probes.
It is important to note that the GSS has to send health probes to all sites or data centers or server load
balancing devices to learn about application availability. The GSS also offers a shared keepalive. With
the shared keepalive, the GSS sends out one request for all the VIPs in a specific data center and gets the
response from all the VIPs in the same response. This is depicted in Figure 10.
Note These health probes have to traverse across the firewalls. The GSS configuration guide provides more
information for deploying GSS behind firewalls.
Moreover, in case of multi-site load distribution, as the number of sites increase, each GSS has to send
health probes to N data centers, N being the number of data centers. The amount of traffic is somewhat
alleviated by the use of KAL-AP health probes.
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Figure 10 Health Probes from GSS
Primary Standby
Keep in mind that the key design goals, when deploying both site-to-site recovery and multi-site loaddistribution, are the following:
Redundancy
High availability
Scalability
Redundancy
Typically, redundancy in a single site is provided by deploying a redundant device in active/standby
mode. A request router, such as a GSS, ACE, or a CSS, is typically connected to the aggregate switch;
these devices can support both link and device redundancy.
To configure the IP address on the GSS interface, use the following command:
gss1.ese-cdn.com# conf t
gss1.ese-cdn.com(config)# interface ethernet 0
gss1.ese-cdn.com(config-eth0)# ip address 172.25.99.100 255.255.255.0
Note While configuring the interface IP addresses, the global site selector services should be stopped using
the gss stop command at the enable mode.
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Now the default gateway on the GSS has to be configured. The default gateway points to the active HSRP
address on the aggregate switches.
gss1.ese-cdn.com# conf t
gss1.ese-cdn.com(config)# ip default-gateway 172.25.99.1
Figure 11 Link and Device Redundancy
Figure 11 depicts the implementation details. The ACEs are deployed in active/standby configuration
with the fault tolerant VLAN carried across the port channel between the two aggregate switches. The
PIX firewalls are also deployed in active/standby configuration. With the aggregate switches and the
access switches running spanning tree, one of the paths is blocked, as shown in Figure 11. Typically, the
aggregate switch on the left is configured as the root for the spanning tree and the aggregate switch onthe right is the secondary root for the spanning tree. With this topology, the GSS is deployed at the access
switch.
Now, a Layer 3 interface is created on both the aggregate switches for the VLAN and are configured as
part of the HSRP group. The aggregate switch on the right hand side is in standby mode. The default
gateway on the GSS points to the active HSRP address. This topology minimizes the impact of aggregate
switch failure. However, if the access switch fails, even though the spanning tree converges to provide
redundancy to the server path, the GSS gets taken out of the picture.
Note There might be more than one client VLAN on the ACE. It is a good idea to put the GSS on a different
VLAN.
Alternatively, the GSS can also be connected directly to the aggregate switch but in this case, if the link
to the GSS fails, the GSS is out of the picture. With the GSS at the access layer, the GSS is protected
from failures to the aggregate switch and failures to the links between the aggregate and the access
switches.
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High Availability
The secondary GSS deployed at the secondary data center also answers DNS queries. Typically, the
upstream DNS round robins are between the primary and secondary GSSs. As long as the primary is
active, it responds to DNS queries and directs the end users to the appropriate data center. If the primary
GSS goes down for any reason, the secondary GSS continues to answer DNS queries.
Scalability
The GSS can scale up to 2000 authoritative domains and up to 8 GSSs can work together in a network.
If there are more than 2 GSSs in the network, one of them is primary, the second one is standby and the
remaining GSSs are configured as GSS.
Basic Configuration
Before getting into implementation details, there are a few basic setup steps that must be done on the
GSSes. These help in enabling the GUI on the GSS. Only the basic steps that are helpful are described
in this section. More details about this are found in the configuration document.All the content routing information is stored in a SQL database. The database files must be created on
the GSSMs before the GUI can be accessed. These are the initial steps to configure a GSS.
Using the SETUP command script you can enter in all of the following information. For those wishing
to do a step-by-step command line implementation, the steps are detailed below.
Step 1 Initial configuration like the IP addresses for the interfaces, the default gateway, the host name and the
name server is configured on the GSS. The name server has to configured on the GSS for the GSS to
work.1
Step 2 Create the data base with the gssm database create command to enable the graphical user interface on
the GSS. This command is executed in the enable mode. Also note that the database is enabled only on
the primary and the standby GSS.Step 3 Configure the node type on the GSS. The node type must be chosen for every GSS in the network. The
different node types are primary, standby, or gss.
Step 4 Enable gss with the gss enable gssm-primary command. Again, this is done from the enable mode. To
follow the activity on the gss, use the show log follow and gss status commands.
Step 5 Follow steps 1-4 for the standby GSS. In step 4, instead of gssm-primary, use the gssm-standby
command to enable the GSS and specify the IP address of the primary GSS.
Step 6 Open a browser window and type https://ip-address-of-gssm-primary as the URL to access the GUI.
Step 7 The default username is admin and the password is default.
The next step is to configure the health probes, answers, answer group, domain lists and balance
methods. This is explained in more detail in both site-to-site recovery and multi-site load distribution
sections.
The information below assists you in understanding the relationship between different configuration
rules, such as DNS rules, Domain lists etc. The DNS rules consist of the following objects. You can get
to each object by clicking on DNS rules and then using the drop down menu on the left hand side.
1. Refer to the GSS configuration guide for more information about the name server.
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Source Address ListA list of addresses of local DNS. For site-to-site recovery, this can be set to
accept all IP addresses. This represents the source that is requesting the IP address of the domain.
Domain ListA list of domains. This represents the list of domains, one of which matches the
domain name requested.
Answer GroupA group of resources from which the answers are provided.
Balance MethodThe global load balancing algorithm that is used to balance responses among the
answer groups.
AnswersConfigure different VIPs here along with the type of keep alive method used.
Shared KeepalivesSpecifies the IP address on the load balancer to which the KAL-AP health
probes are sent.
Both site-to-site recovery and multi-site load distribution use health probes. The different types of health
probes used are shared keepalive and ICMP. Shared keepalive is also called as KAL-AP. There are two
types of KAL-Aps: KAL-AP by VIP and KAL-AP by tag. Shared keepalives can be set up either using
KAL-AP by VIP or KAL-AP by tag. KAL-AP by VIP uses the VIP and KAL-AP by tag uses a domain
string. For KAL-AP by tag, some additional configuration is required on the ACE, which is the load
balancer. The tag specifies the sub-domain and the length of the tag has to be less than 64 characters.
This is because the KAL-AP query limits the length of the tag to 64 characters. The idea behind usingthe domain as a tag is to probe the health of the VIP by domain name instead of the IP address (KAL-AP
by VIP). This comes in handy if the addresses are being translated between the GSS and the load
balancer.
The required configuration on the ACE is as follows:
Probe icmp REAL_Serversip address 10.10.100.1
interval 2
faildetect 1passdetect interval 2
passdetect count 1
rserver host test
ip address 10.10.100.1probe REAL_Serversinservice
serverfarm host REAL_Serversrserver test
inservice
Class-map VIP_200
2 match virtual-address 20.17.30.201 any
Policy-map type loadbalance http first-match real.pol
Class class-default
Serverfarm REAL_Servers
Policy-map multi-match test
Class VIP_200
Loadbalance vip inserviceLoadbalance policy real.pol
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Note When setting up shared keepalives for ACE, the Primary IP address used can be either the IP address of
the client VLAN or the alias IP address of the client VLAN. Also note that if the Content Services Switch
(CSS) is used instead of ACE, use the circuit IP addresses on the CSS in the primary and secondary boxes
of shared keep alive configuration.
Site-to-Site Recovery
In a site-to-site recovery solution, typically, the primary site is the active site and all the end users are
directed to the primary site as long as the applications are alive and well. The secondary site, or the
recovery site, also hosts the applications but these are in a standby mode. The data is replicated to the
standby data center to be used in the event of unexpected downtime at the primary data center.
The site-to-site recovery topology was introduced in Figure 3-1. In this section, the implementation
details for a single site are provided. This design also applies to the secondary site. The only difference
is the configurations on the GSS itself: one is configured as the primary and the second GSS is
configured as the standby GSS.
Note GSS is deployed as authoritative DNS for the sub-domains for critical applications. This implies that the
IP addresses of the authoritative DNS have to be configured in the upstream DNS as name servers.
Typically there is more than one name server in the upstream DNS. During the DNS resolution process,
the upstream DNS uses the round trip time as a measure to query one of the name servers. Site-to-site
recovery is always based on active-standby configurations and regardless of which GSSes are queried,
the result should be the same.
Site Selection Method
The site selection method or balance method, also known as predictor, is the algorithm that is followed
while answering DNS queries from the clients. For site-to-site recovery, where the data centers are in
active/standby mode, a balance method called the ordered list is used.
Using the ordered list balance method, each resource within an answer group (for example, an SLB VIP
or a name server) is assigned a number that corresponds to the rank of that answer within the group.
Devices with lower numbers rank above those with higher numbers.
Using the rankings, the GSS tries each resource in the order that has been prescribed, selecting the first
available (live) answer to serve a user request. List members are given precedence and tried in order.
A member will not be used unless all previous members fail to provide a suitable result.
Configuration
GSSes are configured using GUI. It is difficult to show all the screens in this section to discuss the
configurations. Refer to www.cisco.com for detailed descriptions of the GUI configuration.
Note The TTL (time to live) values configured on the GSS determines for how long the A records are cached.
For site-to-site recovery, setting the TTL to a low value will ensure that a new request is made after the
TTL expiration. It should also be noted that the lowest value of health probe interval that can be set on
the GSS is 45 seconds. The recommended value for TTL on the GSS has to be between 5 and 45 seconds.
This section provides a configuration outline.
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Step 1 Perform initial configurations as described above.
Step 2 On the web browser, use HTTPS to enter the IP address of your primary GSS and login.
Step 3 Once you are on the GSS, the domain list, answer group, balance methods, answers, and shared
keepalives have to be configured either by selecting each of the items individually or by using the wizard.
Step 4 Configure the VIPs by selecting the answers option in the drop down menu for which health probeshave to be sent.
The type of health probes used is also configured here. Different options available are 1. No health probe,
2. ICMP, 3. KAL-AP by VIP and Tag, 4. HTTP-HEAD. For more information on health probes refer
Basic Configuration, page 31.
Step 5 Select the answer groups and configure the members of the answer group. The members of the answer
group are the VIPs.
Step 6 Select the DNS rules from the drop down menu and tie all the information together.
The way the DNS rules read when translated to simple english is For all the clients which belong to this
source list, looking for the sub-domain in the domain list, if the status is active, select one from this
answer group based on the this balance method. 1. For site-to-site recovery, always select ordered list
for balance method. As long as the VIP is alive at the primary site, all clients are directed towards theprimary site.2. The first active address is the primary sites VIP.3. The second active address is the
secondary or standby data centers VIP.
Step 7 Once the configuration is complete, click on Monitoring to view the health information of all the
different VIPs. The following sections describe the configurations for different balance methods.
Figure 12 GSS GUI
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Figure 12 depicts the GSS screen. The drop down menu is on the left hand side of the screen. In the
illustration, you can also see the rule wizard, monitoring, and so forth.
Conclusion
Unlike other global server load balancing devices, the GSS provides all the features in the same chassis.
GSS also provides the decoupling between server load balancer and the global load balancing devices.
GSS interoperates well with the ACE. GSS also provides most of the features and is easier to configure.
GSS does support application high availability, load distribution, and business resilience. Except for a
few features, GSS does meet most of the requirements today. GSS 2.0 and above also offer the ability to
integrate Cisco Network Registrar (CNR) to provide for authoritative DNS services on one platform.
Chapter 4Multi-Site Load Distribution Using DNSYou can achieve redundancy and high availability by deploying multiple data centers and distributing
applications across those data centers. This design document focuses on the design and deployment of
distributed data centers using the Global Site Selector (GSS) and the Application Control Engine (ACE)
This chapter explores interoperability between the GSS and the ACE and also provides details of relevant
algorithms used in multi-site load distribution. These designs are based on request routing products and
the ACE server load balancing product.
Overview
The challenge of geographic load balancing is to ensure that transaction requests from clients are
directed to the most appropriate server load balancing device at the geographically distant data center.
Geographic load distribution requires control points for all transaction requests destined to any data
center. The point of control for a geographic load-distribution function resides within DNS. Most clients
must contact a DNS server to get an IP address to request service from a server. Because, geographically
replicated content and applications reside on servers with unique IP addresses, unique DNS responses
can be provided to queries for the same URLs or applications based on a series of criteria. These different
criteria are based on the availability of applications at different data centers and different metrics. The
different metrics include proximity, weighted round robin, preferred data centers, load at the data center,
etc. The different metrics are dynamically calculated and updated at distributed sites. Based on these
different metrics and the availability of services, clients are directed to the best site.
Benefits
Redundancy, scalability, and high availability are the key benefits of multi-site load distribution.
Site-to-site recovery enables businesses to provide redundancy in case of disasters at the primary datacenters. Multi-site load distribution provides application high availability and scalability. Multi-Site load
distribution provides these benefits by making individual sites look like a single server and getting
application availability and load information from these servers. This makes it possible to deploy
multiple inexpensive devices rather than one large expensive system, providing for incremental
scalability and higher availability.
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Hardware and Software Requirements
The table below lists different hardware and software required to support site-to-site recovery and
multi-site load distribution. The GSS interoperates with the ACE and CSS. It also works with other
server load balancing products, but some of the features, like the least loaded connections and shared
keepalive features, cannot be used with other server load balancers. In subsequent sections of thisdocument, interoperability of the GSS and the ACE is described.
Design Details
Design Goals
The basic design goal is to be able to direct clients to appropriate data center based on the configured
rules and the availability of the servers or services at the data center. The major design issues are:
Redundancy
High availability
Scalability
Security
Other requirements as necessary
Redundancy
Within a data center, redundancy is achieved at different layers. It could be link redundancy or device
redundancy. Redundancy provides a way of maintaining connectivity if there is a failure in the primary
path. This is achieved by deploying devices that support stateful failover.
There are times when the entire data center might go out of service due to an unforeseen reason. In such
cases, clients can be directed to a redundant data center. In the event of a data center fail over, it is
difficult to provide stateful failover. Although, there is some impact due to the failure of primary data
center, the impact is very small compared to not having a redundant design.
High Availability
High availability, from a global server load balancing point of view, is the ability to distribute the load
among available data centers. If, for any reason such as a hardware or software failure or over loaded
data center, it is determined that the new service requests cannot be handled by the data center, the
request is directed to a data center that can really handle the service request. It is the constant monitoring
of application availability and the load at a data center that helps in achieving high availability.
Product Release Platforms
Global Site Selector (GSS)2.0.2.0.0 (this software version
was used for testing)GSS-4492R
Application Control Engine
(ACE)
1.6.1 (this software version was
used for testing)
SLB complex for Catalyst 6K
platforms
Cisco Network Registrar (CNR) 6.2.3.2 (this software version
was used for testing)
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High availability is also prevalent at each layer of the network including Layer 2 and Layer 3. For a more
detailed description of how high availability is achieved within a data center, refer to the Data Center
Networking: Infrastructure Architecture SRND:
http://www.cisco.com/en/US/docs/solutions/Enterprise/Data_Center/DC_Infra2_5/DCI_SRND_2_5_b
ook.html.
Scalability
Scalability is an inherent element of distributed data center environment. Applications can be hosted at
multiple data centers to distribute the load across multiple data centers and make the applications
scalable and highly available. The design should be able to